Differential pressure actuated switch with high speed latch means



March 18, 1969 i o. JENSEN 3,433,911

DIFFERENTIAL PRESSURE ACTUATED swrrcn wma men SPEED LATCH MEANS Filed on. 12, 1966 Sheet of 4 March 18, 1969 o. JENSEN DIFFERENTIAL PRESSURE ACTUATED SWITCH WITH HIGH SPEED LATCH MEANS Filed Oct. 12. 1966 Sheet 2 of drum; EMA, fiance, 622a {far/av March 18, 1969 0, JENSEN 3,433,911

DIFFERENTIAL PRESSURE ACTUATED SWITCH WITH v HIGH SPEED LATCH MEANS Filed Oct. 12. 1966 Sheet '2' of 4 O. JENSEN March 18. 1969 DIFFERENTIAL PRESSURE ACTUATED SWITCH WITH Sheet 4 of 4 v v HIGH SPEED LATCH MEANS Filed Oct. 112. 1966 f IN ENTOR. 077V JE IVSE/V United States Patent 3,433,911 DIFFERENTIAL PRESSURE ACTUATED SWITCH WITH HIGH SPEED LATCH MEANS Otto Jensen, Malvern, Pa., assignor to I-T-E Circuit Breaker Company, Philadelphia, Pa., a corporation of Pennsylvania Filed Oct. 12, 1966, Ser. No. 586,238 US. Cl. 200-83 Int. Cl. H01h 35/40, 1 64 6 Claims ABSTRACT OF THE DISCLOSURE This invention relates to electrical switches, and more specifically relates to a novel ultra high speed electrical switch for closing an electrical circuit some very short and controlled predetermined time after the initiation of a closing signal.

Very fast operation is essential in some switches which are used to by-pass faulted equipment or to apply an intentional fault of an electrical component during test conditions.

Thus, in circuit breaker testing, it is common practice to initiate a fault or short-circuit at a pre-selected instant on the applied voltage wave. For good test results, it is essential that the fault start at this very accurate and preselected time. Another example of such devices, shortcircuiters are Well-known for the protection of electrical equipment wherein the short circuiter will form a parallel path about the equipment to protect it from a fault circuit condition. In these typical applications, consistent closing time and fast operation are essential.

Switches of this type must be able to withstand normal voltage across their open contacts, and must be able to carry very large currents for several seconds. In order to satisfactorily withstand voltage, the open switch gap must be wide. This will increase the contact travel required for closing and increases the demands on acceleration necessary to complete the closing motion in a very short time.

The problem is further aggravated by the requirement of the device to carry heavy currents which requires that the moving contact is normally very heavy, thus increasing the force required for high acceleration.

The required heavy closing forces further create their own problems such as contact bounce during closing which results in erosion and cause frictional drag which causes erratic closing times.

Another problem commonly associated with making switches is pie-arcing, which consists of the dielectric break-down of the contact gap while the contacts are approaching one another, which goes into a high current are until metallic contact is made. This pre-arcing will also introduce errors in the time of initiation of a fault current and produces severe contact erosion.

The present invention provides a novel closing switch which substantially overcomes all of the above noted previously existing problems with this type of apparatus. In accordance with the invention, a movable contact carried on a flexible diaphragm is supported within a sealed 3,433,911 Patented Mar. 18, 1969 chamber which is filled with some suitable high dielectric gas. The contacts are now carried in a sealed chamber, and are moved by the differential pressure on opposite sides of the support diaphragm with the contacts normally latched open by a suitable high accuracy, high speed latch such as a roller latch. Thus, extremely fast movement of the contact can be obtained. Moreover, smaller open-contact spacing can 'be used, and less pro-arcing occurs due to the high dielectric medium in which the contacts are immersed.

In addition, since the switch is operated by gas pressure differentials, very high contact operating forces can be obtained to decrease and eliminate contact bounce, and relatively heavy moving parts can be used to satisfy the high load current capacity of the device when it is closed.

Finally, the complete structure is arranged in a U- shaped path in such a manner that the magnetic forces caused by current flow through the contact tend to hold the contact closed with the well-known blow-on effect.

A high speed release mechanism for operating the system to its closed position then incorporates a roller latch which is operated by the repulsion of a short-circuited turn, movable 'with the roller latch, which is enengized by a stationarily mounted Winding which induces current in the short-circuited turn to cause magnetic repulsion and high speed removal Olf the latch.

Accordingly, a primary object of this invention is to provide a novel high speed making switch.

Another object of this invention is to provide a high speed making switch which is closed at a consistent closing time after the reception of an operating impulse.

Another object of this invention is to provide a novel high speed making switch which substantially eliminates pro-arcing, thereby improving operating time consistency.

Still another object of this invention is to provide a novel high speed making switch which has a relatively short switch-open gap to withstand normal voltage across its open contacts.

A further object of this invention is to provide a novel high speed making switch which is capable of conduction of very large currents for several seconds.

Still another object of this invention is to provide a novel high speed making switch which is pneumatically operated, whereby high operating forces can be used for the acceleration of relatively low mass moving components.

These and other objects of this invention will become apparent from the following description when taken in connection with the drawings, in which:

FIGURE 1 is a side plan view of the novel making switch of the invention.

FIGURE 2 is a top view of FIGURE 1.

FIGURE 3 is a cross-sectional view of FIGURE 1 taken across the line 33 in FIGURE 1.

FIGURE 4 is a cross-sectional view of FIGURE 3 taken across the line 44 in FIGURE 3.

FIGURE 5 is a partial cross-sectional view of FIGURE 3 taken across the line 55 in FIGURE 3.

Referring now to the drawings and particularly FIG- URES l, 2 and 3, the device of the invention is provided with two threaded terminals 10 and 11 which are mounted in an insulation body 12 and are embedded therein. Body 12 may be of any suitable epoxy, or the like, and forms an air-tight seal about flanges 13 and 14 of conductive terminals 10 and -11, and could include suitable gaskets such as gaskets 15 and 16.

A pair of stationary contacts 20 and 21 which have the shape shown in dotted lines in FIGURE 4 then seat atop the upper ends of electrodes 10 and 111 and are mechanically and electrically connected thereto by suitable bolts such as the bolt 22, shown in FIGURES 3 and 4, along with two similar spaced bolts which pass through the tapped openings 23 and 24 in stationary contact as shown in FIGURES 3 and 4, to engage outwardly disposed regions of the end of the terminal 11 adjacent stationary contact 20.

In a similar manner, three bolts 25, 26 and 27 connect stationary contact 21 to the upper end of terminal 10, as shown in FIGURE 4.

To further provide secure connection between stationary contacts 20 and 21 and their terminals 11 and 10, respectively, upper insulating pressure disc 30, shown in FIGURE 3, seats atop stationary contacts 20 and 21.

The disc will have suitable openings therethrough conforming to the locations of screws 22, 23, 24 and screws 25, 26 and 27, and will further have openings therein for the reception of bolts such as bolt 32, shown in FIGURES 3 and 4, for the direct securement of the stationary contacts 20 and 21 to their conductive members 30 and 31. Additional support bolts may also be provided for this function such as support bolts 33 and 34 for connecting disc 30 to terminal -11, while the bolts 35, 36 and 37 connect disc 30 to terminal 10.

A top support structure 40 which is of metallic material such as aluminum is then provided atop the housing 12 and is secured to the housing 12 as by a plurality of bolts, such as bolt 41, which encircle the top of the cap 40. The cap 40 further provides mechanical securement for the insulation material support diaphragm 42 which will be described more fully hereinafter as the support for the movable contact structure, and which may be made of any suitable resilient material such as a suitable rubber composition material such as Neoprene.

The diaphragm 42 extends completely across the upper surface of housing 12 and defines a sealed chamber 43 which may be connected by a suitable outlet nipple 44 to a suitable source of high pressure gas such as sulphur hexafluoride which can fill chamber 43 under high pressure.

A second chamber 45 is defined atop diaphragm 42, and is enclosed by a second rubber composition diaphragm 46 which is connected to the cap 40 by a second cap 47 which may be of insulation material. The second cap 47 is secured to the cap 40 by suitable bolts such as bolt 48, best shown in FIGURES 2 and 3, which encircle cap 47.

The chamber 45 defined between diaphragms 42 and 46 is then normally connected to external atmosphere by means of a plurality of vents such as vent 50 which extend around the periphery of cap 40.

Diaphragm 42 then carries a movable conductive rod 51, best shown in FIGURE 3, which is connected to diaphragm 42 by a lock-nut 52 threaded on the threaded region of rod 51 and abutting against the first extending flange 53 extending from rod 51. The lower end of rod 51 is then suitably secured in any desired manner to a conically shaped movable contact 54 by means of the conical nut 55 which is forced into the conical opening of contact 54 by the bolt 56 which is threaded into the end of rod 51. Note that the conical movable contact 54 is movable into and out of bridging engagement with cooperating arcuate segments 60 and 61 of the stationary contacts 20 and 21, respectively, the shapes of which are best shown in FIGURE 4.

The upper end of rod 51 beyond flange 53 threadably passes through a stop member 65 which is carried on diaphragm 46 by means of a lock-nut 66 threaded to the extending stem portion of member 65 extending through diaphragm 46. The uppermost end of rod 51 then receives a latch receiving member 70 which is secured thereto as by threading in the manner illustrated. Note that the latch-receiving member 70 passes through a central opening in the upper cup 47 through a sealing gasket 71.

From the foregoing structure, it will be seen that the movable contact 54 can move upwardly into engagement 4 with contacts 20 and 21 when the rod 51 is moved upwardly, this motion being permitted by the flexing of diaphragm 42 under the differential pressure applied thereacross with the upward motion of rod 51 being permitted when the latch receiving member 70 is free to move upwardly.

This motion is caused by the high pressure gas within volume 43 below diaphragm 42 when the chamber 45 on top of diaphragm 42 is vented to open air. This high pressure gas also serves the function of preventing pre-arcing between movable contact 54 and stationary contacts 30 and 31. Moreover, the provision of the high pressure gas permits the use of a smaller open-gap spacing betweenthe cooperating contacts to withstand the normal voltage conditions across the open contacts so that relatively short contact travel is required to close the switch.

The closing operation of the switch can be obtained by introducing a sufliciently high pressure in volume through the opening 81 which will cause diaphragm 46 to move downwardly with the member 65 moving into engagement with flange 53, thereby to move the flange, and thus stem 51, downwardly to the normal open position of the switch and to permit the resetting of the latch.

It will be apparent that any suitable high latch speed mechanism could be used with the novel switch construction of the drawings. For purposes of illustration, the present disclosure describes a roller latch structure for the latch function. More particularly, the latch structure is generally supported between a pair of upstanding arms 101 and 102 which are bolted to the upper cap 47 as by bolts 103-104 and 105406, respectively, as best shown in FIGURE 2.

A pivotally mounted shaft 107 is supported between support arms 101 and 102 and pivotally carries a metallic rotatable latch arm 108 which has a hardened steel latch plate 109 connected at the bottom thereof. The bottom of latch plate 109 then cooperates with a roller latch 110 which is carried in a triangular opening 1110a of a U-shaped frame 111 which is suitably secured to the upper cap 47. The roller latch is movable along the bottom of triangular opening 110a, and is biased to the right in FIGURE 3 by schematically illustrated spring 1101).

Frame 111 is adjustably located on latch surface 70 by adjustment of adjusting screw 31 to cause the latch plate to rest on roller 110 so that the center line of the roller is about 0.015 inch behind the right vertical edge of latch plate 109.

The latch arm 108 is rotatable in a clockwise direction in FIGURE 3 against a suitable motion bufler structure which is suitably mounted between arms 101 and 102, while the upper end of latch arm 109 extending above the pivot 107 has a position switch operating extension 121 which operates the contact actuator 122 of a microswitch 123 which is supported between arms 101 and 102 in any desired manner.

In operation, the latch arm 108 is normally biased to the position shown in FIGURE 3 by means of the biasing spring 131 extending between arm 108 and the buffer structure 120. An operating winding which is insulated from conductive arm 108 by epoxy disc is then embedded in a stationary mounted adjustment structure 133 which is supported between arms 101 and 102. Energization of winding 132, as by a capacitor discharge circuit,

will induce current flow in the conductive latch arm 108. This induces circulating current in the effective short-circuited turn of conductive latch arm 108 and strong repulsion forces will exist between latch arm 108 and winding 132 which will cause the rapid clockwise rotation of latch arm 108 about its pivot 107. This motion is subsequently arrested by the buffer 120.

When the latch plate 109 moves off the roller 110, roller 110 can rotate with respect to its support, thereby permitting the high pressure in chamber 43 to press rod 51 upwardly with an extremely rapid motion, thereby to cause contact engagement of contact 54 with the fixed contacts and 21.

In order to adjust the latching mechanism, a micrometer adjusting structure is provided. The adjustment is obtained in two ways. The first consists of adjusting the impulse coil structure 133 to position the right-hand vertical surface of latch plate 109 approximately 0.015 inch beyond the center line of shaft 51. The remaining portion of the micrometer adjustment consists of the proper positioning of latch roller 110, as described previously.

In order to reopen the switch and to permit the relatching of latch plate 109 and latch roller 110, air pressure is applied to chamber 80 above diaphragm 46 through the air pressure connection conduit 81. This presses member '65 downwardly until it engages flange 53, whereupon flange 53 and its rod 51 will move downwardly as a single unit, thereby to move contact 54 to its normal open position. At the same time, the upper latching surface 70 will move below latch roller 110 so that latch plate 109 can seat atop the latch plate 110 with the latch bite called for by the latch adjustment mechanism. Note that the microswitch 123 can be connected in a suitable electrical circuit which will indicate the open or closed condition of contacts 54, 20 and 21 through the location of pivot arm 108.

Although this invention has been described with respect to its preferred embodiments, it should be understood that many variations and modifications will now be obvious to those skilled in the art.

The embodiments of the invention in which an exclusive privilege or property is claimed are defined as follows:

1. A high speed making switch comprising first and second contact spaced stationary contacts, a movable contact movable into and out of engagement with said first and second stationary contact; a first enclosed chamber hermetically sealing said first and second stationary contacts and said movable contact; high pressure gas in said first enclosed chamber; a first flexible diaphragm forming one wall of said first enclosed chamber; said movable contact connected to the side of said first flexible diaphragm interior of said first enclosed chamber; the exterior side of said first flexible diaphragm connected to a relatively low pressure region compared to the pressure of said high pressure gas; extending latch rod means connected to said movable contact and extending outwardly of said first enclosed chamber and from the said exterior of said diaphragm; and latch means cooperating with said latch rod and movable between a latched and unlatched position with respect to said latch rod; said latch means holding said movable contact spaced from said first and second stationary contacts when in said latched position with respect to said latch rod against the differential pressure across said first diaphragm; said first diaphragm flexing in a direction to move said movable contact into engagement with said first and second stationary contacts when said latch means is in its said unlatched position under the force of the differential pressure across said first diaphragm.

2. The device as set forth in claim 1 which includes opening means connected to said movable contact for moving said movable contact out of engagement with said first and second stationary contacts and permitting the latching of said latch means.

3. The device as set forth in claim 1 wherein said opening means includes a second diaphragm forming one wall of a second sealed chamber; said latch rod extending through said second sealed closure; a lost motion connection connecting said second diaphragm to said latch rod whereby the application of pressure in said second chamber moves said diaphragm into engagement with said latch rod to move said contact out of engagement with said first and second stationary contacts.

4. The device as set forth in claim 1 which includes first and second elongated terminal conductors connected to said first and second contacts, respectively; said first and second terminal conductors parallel to one another and defining the arms of a U-shaped current path which includes said first and second stationary contacts at the bottom of said U; said U-shaped current path defining a blow-on effect for moving said movable contact into high force engagement with said first and second stationary contacts when current flows in said U-shaped path.

5. The device as set forth in claim 4 wherein said U- shaped current path is substantially embedded in an insulation housing; a portion of said insulation housing defining a portion of the walls of said first hermetically sealed enclosure.

6. A high speed making switch comprising; a stationary contact, a movable contact movable into and out of engagement with said stationary contact, an enclosed chamber hermetically sealing said stationary and movable contacts, a high dielectric high pressure gas in said enclosed chamber, a flexible diaphragm forming one wall of said enclosed chamber; said movable contact connected to the side of said flexible diaphragm interior of said enclosed chamber; the exterior side of said flexible diaphragm connected to a relatively low pressure region compared to the pressure of said high pressure gas; and operating rod means connected to said movable contact and extending outwardly of said enclosed chamber and from the exterior of said flexible diaphragm; latch means cooperating with said operating rod means and movable between a latched and unlatched position with respect to said operating rod means; said latch means holding said operating rod and said movable contact in one of its engaged or disengaged positions with respect to said stationary contact against the force due to differential pressure across said flexible diaphragm when said latch means is in its said latched position; said flexible diaphragm moving said movable contact to the other of its engaged or disengaged positions with respect to said stationary contact when said latch means moves to its said unlatched position.

References Cited UNITED STATES PATENTS 2,270,608 1/ 1942 Sandberg 202-83 2,537,474 1/1951 Mejean 20083.2 XR 2,648,732 8/1953 Starbird 20083.2 XR 2,767,277 10/ 1956 Wirth 200-83 2,837,611 6/1958 Detwiler et a1 ZOO-83.5 3,224,251 12/1965 Minix 200-83.91 XR ROBERT K. SCHAEFER, Primary Examiner.

H. BURPS, Assistant Examiner. 

